JP2014176288A - Motive power generating device using inertial force as motive power and power generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a motive power generating device using an inertial force as motive power and having a compact and simple structure, and a power generator equipped with a generator actuated by motive power generated by the motive power generating device.SOLUTION: A motive power generating device includes: a rotor 1 supported by a post 4; a polygonal rail 2 installed in the rotor 1; a plurality of movable weights 3 which are driven and controlled by a drive device and a control device. A power generator includes: the motive power generating device using a moment of inertia as motive power which is generated by consequently driving the movable weights 3 in accordance with rotation of the rotor 1 along the rail 2; and a generator 5 actuated by motive power generated by the motive power generating device.

Description

  The present invention relates to a power generation device and a power generation device that use inertial force as power.

  In recent years, due to consideration for the global environment, in the field of power generation, there has been a movement to shift its power from fossil fuels and nuclear power to wind power and sunlight using natural energy.

JP 2004-124932 A

However, such a power generation device using natural energy has a problem that it cannot sustain stable power generation due to the instability of natural energy, which is greatly restricted by its installation location and installation space. .
Therefore, the present invention provides a power generation device including a power generation device having a small and simple structure that uses inertial force as a power, and a generator that operates with the power generated by the power generation device. Objective.

1st invention is equipped with the rotary body 1 supported by the support | pillar 4, the polygonal rail 2 installed in this rotary body 1, and the several movable weight 3 driven and controlled by a drive device and a control apparatus. The power generating device uses the moment of inertia generated by sequentially driving the movable weight 3 along the rail 2 in accordance with the rotation of the rotating body 1 as power.
The second invention is a power generation device including the power generation device of the first invention and the generator 5 that operates with the power generated by the power generation device.

  According to the first and second aspects of the invention, it is environmentally friendly and can generate stable power and generate electricity at a low cost with a small and simple structure regardless of the installation location.

  The generated power amount and power generation amount can be adjusted by increasing or decreasing each element of the diameter of the rotating body 1, the mass of the movable weight 3, and the moving speed of the movable weight 3.

It is a rough front explanatory view of a power generator showing an embodiment of this invention. It is a rough front explanatory drawing at the time of 30 degree rotation of the electric power generating apparatus rotary body of FIG. It is a rough front explanatory drawing at the time of 60 degree rotation of the electric power generating apparatus rotary body of FIG. FIG. 2 is a schematic front explanatory view when the power generator rotator of FIG. 1 is rotated by 90 degrees. FIG. 2 is a schematic front explanatory view when the power generator rotator of FIG. 1 is rotated 120 degrees.

An embodiment of the present invention is shown in FIGS.
A rotating body 1 supported by a support column 4, an equilateral triangular rail 2 installed in the rotating body 1, and two movable weights 3 driven and controlled by a driving device and a control device. The generator 5 is operated to generate electric power by a power generating device that uses the moment of inertia generated by sequentially driving the movable weight 3 along the rail 2 in accordance with the rotation of the generator 5.

  First, in FIG. 1, one of two movable weights 3 of the same mass arranged at two apexes of a triangle of a regular triangular rail 2 installed in a rotating body 1 supported by a support 4 is the rotating body 1. It is in the state which is located in the lowest point.

  FIG. 2 shows a state in which one of the movable weights 3 is driven a distance of 1/4 of the hypotenuse length of the equilateral triangular rail 2 when the rotating body 1 rotates 30 degrees.

  FIG. 3 shows a state in which one of the movable weights 3 has driven a distance that is ½ of the hypotenuse length of the regular triangular rail 2 when the rotating body 1 rotates 60 degrees.

  FIG. 4 shows a state in which one of the movable weights 3 has driven a distance of 3/4 of the hypotenuse length of the equilateral triangular rail 2 when the rotating body 1 rotates 90 degrees.

  FIG. 5 shows a state in which one of the movable weights 3 drives the entire distance of the hypotenuse length of the equilateral triangle rail 2 when the rotating body 1 rotates 120 degrees, and is the same state as FIG.

At this time, assuming that the counterclockwise moment of inertia is Mg, the mass of one movable weight 3 is W, and the horizontal distance from the center of the rotating body 1 to the movable weight 3 is L1 and L2, respectively. When 5, Mg = W × L1
2 and 3, Mg = W (L1−L2) where L1> L2
In the case of FIG. 4, Mg = W (L1 + L2)
Thus, it is possible to continue to rotate the rotating body 1 by generating a counterclockwise moment of inertia in any state during 120 ° rotation.

Further, since the work amount = mass × the movement distance, the relationship between the work amount for rotating the rotating body 1 and the work amount for driving the movable weight 3 is expressed as follows: mass of the rotating body 1 × r 2rπ ÷ 3> mass of movable weight 3 × 2rcos30
It becomes.

  As described above, the generator 5 can be operated by the generated rotational power to generate power.

  The generated power amount and power generation amount can be adjusted by increasing or decreasing each element of the diameter of the rotating body 1, the mass of the movable weight 3, and the moving speed of the movable weight 3.

1 Rotating body 2 Rail 3 Movable weight 4 Strut 5 Generator

Claims (2)

  A rotating body supported by a support; a polygonal rail installed in the rotating body; and a plurality of movable weights driven and controlled by a driving device and a control device. A power generation apparatus characterized in that a moment of inertia generated by sequentially driving weights along the rail is used as power.   A power generation device comprising: the power generation device according to claim 1; and a generator that operates with power generated by the power generation device.

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